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A mathematical model of the deposition rate and layer height during electrochemical additive manufacturing

Electrochemical additive manufacturing (ECAM) is a novel non-thermal metal additive manufacturing technology. The layer height is an important parameter in additive manufacturing processes which determines the resolution and quality of the parts manufactured. The modeling of the rate of deposition e...

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Published in:	International journal of advanced manufacturing technology 2019-06, Vol.102 (5-8), p.2367-2374
Main Authors:	Kamaraj, Abishek B., Sundaram, Murali
Format:	Article
Language:	English
Subjects:	Additive manufacturing CAE) and Design Computer-Aided Engineering (CAD Deposition Engineering Hardware reviews Industrial and Production Engineering Ion transport Mathematical models Mechanical Engineering Media Management Original Article Predictions Process parameters
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container_issue	5-8
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container_title	International journal of advanced manufacturing technology
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creator	Kamaraj, Abishek B. Sundaram, Murali
description	Electrochemical additive manufacturing (ECAM) is a novel non-thermal metal additive manufacturing technology. The layer height is an important parameter in additive manufacturing processes which determines the resolution and quality of the parts manufactured. The modeling of the rate of deposition enables the prediction of the layer size and time of deposition for a particular feature. The developed model takes the electrical process parameters and the horizontal scan speed as inputs and gives the rate of deposition and deposited layer height as the output. The current density was calculated based on an existing model considering ion transport and electrode kinetics. The predicted deposition rates were validated with experimental findings. It was found that the pulsed voltage with a 75% duty cycle had the highest deposition rate. While the deposition rates varied between 1 and 3 μm/s, the scan speed was found to be between 0.1 to 2 mm/s for a diameter 250-μm tool. The scan speed had a lower limit for each interelectrode gap below which a possibility of short-circuiting exists. The influence of the pulse duty cycle on the layer height reduces at larger interelectrode gaps.
doi_str_mv	10.1007/s00170-019-03292-2
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subjects	Additive manufacturing CAE) and Design Computer-Aided Engineering (CAD Deposition Engineering Hardware reviews Industrial and Production Engineering Ion transport Mathematical models Mechanical Engineering Media Management Original Article Predictions Process parameters
title	A mathematical model of the deposition rate and layer height during electrochemical additive manufacturing
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